Bacteria

About: Bacteria is a research topic. Over the lifetime, 23676 publications have been published within this topic receiving 715990 citations. The topic is also known as: eubacteria.

The purple phototrophic bacteria

Abstract: The first € price and the £ and $ price are net prices, subject to local VAT. Prices indicated with * include VAT for books; the €(D) includes 7% for Germany, the €(A) includes 10% for Austria. Prices indicated with ** include VAT for electronic products; 19% for Germany, 20% for Austria. All prices exclusive of carriage charges. Prices and other details are subject to change without notice. All errors and omissions excepted. C.N. Hunter, F. Daldal, M.C. Thurnauer, J.Th. Beatty (Eds.) The Purple Phototrophic Bacteria

Sensitive Quantitative Detection of Commensal Bacteria by rRNA-Targeted Reverse Transcription-PCR

Abstract: A sensitive rRNA-targeted reverse transcription-quantitative PCR (RT-qPCR) method was developed for exact and sensitive enumeration of subdominant bacterial populations. Using group- or species-specific primers for 16S or 23S rRNA, analytical curves were constructed for Escherichia coli, Enterococcus faecalis, Staphylococcus aureus, Clostridium perfringens, and Pseudomonas aeruginosa, and the threshold cycle value was found to be linear up to an RNA amount of 10−3 cell per RT-PCR. The number of bacteria in culture was determined by RT-qPCR, and the results correlated well with the CFU count over the range from 100 to 105 CFU. The bacterial counts obtained by RT-qPCR were the same as the CFU counts irrespective of the growth phase in vitro, except for C. perfringens during starvation periods; the viable cell counts obtained by using a combination of 4′,6-diamidino-2-phenylindole (DAPI) staining and SYTO9-propidium iodide double staining were in good agreement with the RT-qPCR counts rather than with the CFU counts. The RT-qPCR method could detect endogenous Enterobacteriaceae and P. aeruginosa in feces of hospitalized patients (n = 38) at a level of 103 cells per g of feces, and for enumeration of S. aureus or P. aeruginosa spiked into human peripheral blood, the lower detection limit for RT-qPCR quantification of the bacteria was 2 cells per ml of blood, suggesting that this method was equivalent to the conventional culture method. As only 5 h was needed for RT-qPCR quantification, we suggest that rRNA-targeted RT-qPCR assays provide a sensitive and convenient system for quantification of commensal bacteria and for examining their possible invasion of a host.

Ionophore resistance of ruminal bacteria and its potential impact on human health.

Abstract: In recent years, there has been a debate concerning the causes of antibiotic resistance and the steps that should be taken. Beef cattle in feedlots are routinely fed a class of antibiotics known as ionophores, and these compounds increase feed efficiency by as much as 10%. Some groups have argued that ionophore resistance poses the same public health threat as conventional antibiotics, but humans are not given ionophores to combat bacterial infection. Many ruminal bacteria are ionophore-resistant, but until recently the mechanism of this resistance was not well defined. Ionophores are highly lipophilic polyethers that accumulate in cell membranes and catalyze rapid ion movement. When sensitive bacteria counteract futile ion flux with membrane ATPases and transporters, they are eventually de-energized. Aerobic bacteria and mammalian enzymes can degrade ionophores, but these pathways are oxygen-dependent and not functional in anaerobic environments like the rumen or lower GI tract. Gram-positive ruminal bacteria are in many cases more sensitive to ionophores than Gram-negative species, but this model of resistance is not always clear-cut. Some Gram-negative ruminal bacteria are initially ionophore-sensitive, and even Gram-positive bacteria can adapt. Ionophore resistance appears to be mediated by extracellular polysaccharides (glycocalyx) that exclude ionophores from the cell membrane. Because cattle not receiving ionophores have large populations of resistant bacteria, it appears that this trait is due to a physiological selection rather than a mutation per se. Genes responsible for ionophore resistance in ruminal bacteria have not been identified, but there is little evidence that ionophore resistance can be spread from one bacterium to another. Given these observations, use of ionophores in animal feed is not likely to have a significant impact on the transfer of antibiotic resistance from animals to man.

Antibiotic tolerance among clinical isolates of bacteria.

Abstract: One of the unique features of p-lactam antibiotics and other cell-wall inhibitors like vancomycin and bacitracin is that they can rapidly kill and in many cases lyse susceptible bacteria. Many other types of antibacterial agents (e.g., trimethoprim or chloramphenicol) are primarily bacteriostatic: they inhibit multiplication but do not cause an irreversible inactivation of the cell. In 1970 the characterization of a novel type of pneumococcal mutant was reported in the literature [1]. This mutant grows in normal generation times and is as sensitive to growth inhibition by penicillin as the wild-type parent strain. However, while cultures of the parent

Two classes of metabolites from Theonella swinhoei are localized in distinct populations of bacterial symbionts.

Abstract: The marine spongeTheonella swinhoei (lithistid Family Theonellidae, Order Astrophorida) has yielded many important, bioactive natural products, most of which share structural features with bacterial natural products. The presence of microbial symbionts inT. swinhoei has been reported, and it was originally suggested that the cytotoxic macrolide swinholide A and many of the bioactive cyclic peptides fromT. swinhoei were all produced by symbiotic cyanobacteria. By transmission electron microscopy, we found four distinct cell populations to be consistently present inT. swinhoei: eukaryotic sponge cells, unicellular heterotrophic bacteria, unicellular cyanobacteria and filamentous heterotrophic bacteria. Purification and chemical analyses of each cell type showed the macrolide swinholide A to be limited to the mixed population of unicellular heterotrophic bacteria, and an anti-fungal cyclic peptide occurred only in the filamentous heterotrophic bacteria. Contrary to prior speculation, no major metabolites were located in the cyanobacteria or sponge cells.